Application of CFD Analytical Tools in Architectural Design in the Context of Wind Loads – Part 1

1. Anderson J.D. Jr. (2008), Some Reflections on the History of Fluid Dynamics, in: The Handbook of Fluid Dynamics, ed. R.W. Johnson, CRC Press–Springer, Boca Raton–Heidelberg. Search in Google Scholar

2. Autodesk Support (2023), Flow Design vs. Autodesk CFD, https://www.autodesk.com/support/technical/article/caas/sfdcarticles/sfdcarticles/Flow-Design-vs-Autodesk-CFD.html [access: 1.07.2024]. Search in Google Scholar

3. Cholewiński M. (2021), Budowa obserwatorium na Śnieżce 1973 r., https://fotopolska.eu/Sniezka-_1602_m_n.p.m.,552,48?f=1772421-foto [access: 1.07.2024]. Search in Google Scholar

4. Designing Buildings (2022), Aerodynamics, https://www.designingbuildings.co.uk/wiki/Aerodynamics [access: 1.07.2024]. Search in Google Scholar

5. Gadomska P. (2020), Będzie remont Marsjańskich Spodków Śnieżki, ale kiedy?, “Jelenia Góra Nasze Miasto”, 5 marca. Search in Google Scholar

6. Geurts C.P.W. (2005), The use of wind tunnel experiments for wind loads on structures, TNO Built Environment and Geosciences, Delft, The Netherlands. Search in Google Scholar

7. Kaijima S., Bouffanais R., Willcox K., Naidu S. (2013), Computational fluid dynamics for architectural design, “Architectural Design”, 83(2), 118–123. Search in Google Scholar

8. Kolarevic B. (2003), Computing the performative in architecture, in: Proceedings of the 21th eCAADe Conference: Digital Design. Graz, Austria, 17–20. Search in Google Scholar

9. Kolarevic B., Malkawi A.M. (2005), Performative Architecture: Beyond Instrumentality, Spon Press, New York–London. Search in Google Scholar

10. Kowalska M. (2021), Remont obserwatorium na Śnieżce jeszcze w tym roku, „Architektura & Biznes”, https://www.architekturaibiznes.pl/juz-niebawemremont-obserwatorium-na-sniezce,7524.html [access: 1.07.2024]. Search in Google Scholar

11. Kyoto Protocol (1998), Kyoto Protocol to the United Nations framework convention on climate change, Kyoto. Search in Google Scholar

12. Larosea G.L., Franck N. (1997), Early wind engineering experiments in Denmark, “Journal of Wind Engineering and Industrial Aerodynamics”, 72, 493–499. Search in Google Scholar

13. Laboratorium Inżynierii Wiatrowej Politechnika Krakowska (2008), http://www.windlab.pl/zrealizowane-prace/pulawska_warszawa/ [access: 1.07.2024]. Search in Google Scholar

14. Laboratorium Inżynierii Wiatrowej Politechnika Krakowska (2013), http://www.windlab.pl/zrealizowane-prace/grzybowska_warszawa/ [access: 1.07.2024]. Search in Google Scholar

15. Ladybug Tools LLC (2023), Butterfly, https://www.ladybug.tools/butterfly.html [access: 1.07.2024]. Search in Google Scholar

16. National Academies of Sciences, Engineering, and Medicine (2016), Attribution of extreme weather events in the context of climate change, National Academies Press. Search in Google Scholar

17. Nova A. (2006), The role of the winds in architectural theory from Vitruvius to Scamozzi, in: Aeolian winds and the spirit in Renaissance architecture, ed. B. Kenda, Academia Eolia revisited, London, 70–86. Search in Google Scholar

18. Ramotowski J. (2012), Profesor architekt Witold Lipiński i jego pasje, “Studia Łomżyńskie”, 23, 217–225. Search in Google Scholar

19. TOI: Design Informatics (2020), Flow Design – wind simulation, TU Delft, Faculty of Architecture, http://wiki.bk.tudelft.nl/toi-pedia/Flow_Design_-_windsimulation [access: 10.12.2023]. Search in Google Scholar

20. Wojciechowski Ł. (2014), Pierwsze w Polsce – Kosmiczne obserwatorium, “Architektura Murator”, 3, 20–21. Search in Google Scholar

21. Yao J.W., Lin Y.Q., Zheng J.Y., Yuan P.F. (2018), A “Dynamic Form-Finding”. Approach to Environmental-Performance Building Design, “International Journal of High-Rise Buildings”, 7(2), 145–151. Search in Google Scholar